Deck 18: The Structure of the Atom

A) not as close together as they should be.
B) held together by electrical forces.
C) themselves mostly empty space.
D) in perpetual motion.

A) 2.
B) 4.
C) 6.
D) 8.
E) unlimited.

A) Gamma rays.
B) Protons.
C) X-rays.
D) Electrons.
E) Alpha particles.

A) no electric charges in it.
B) no nuclei in it.
C) electrons that are not attracted to nuclei.
D) enough positive charge in the nuclei to balance the negative charge of the electrons.

A) Electrons in certain orbits do not radiate electromagnetic waves despite being centripetally accelerated.
B) All atoms contain "special" electrons that do not radiate their energy.
C) The electrons in some orbits are paired so as to become stable.
D) The stable orbits are maximally occupied with electrons.

A) gravitational force with the nucleus.
B) magnetic force between the electrons.
C) electrical force with the nucleus.
D) nuclear force with the nucleus.

A) can emit radiation at frequencies only within the visible spectrum.
B) can emit radiation only at specific frequencies.
C) all have the same number of electrons.
D) can emit radiation at any frequency.

A) light can only behave like a particle in atoms.
B) light can behave like a wave or a particle depending on the situation.
C) light waves do not carry energy but photons can.
D) photons do not have a frequency.

A) have a simple ratio of masses.
B) have equal masses.
C) have identical chemical properties.
D) have similar chemical properties.

A) atoms get rearranged.
B) a substance gets hot.
C) atomic nuclei change form.
D) atoms change mass.

A) dissolving the lead in acid so that it loses enough mass to have the same mass as mercury.
B) grinding the lead to dust and then melting the dust.
C) heating the lead to extremely high temperatures.
D) none of these.

A) are basically unstable.
B) all have the same number of electrons.
C) are big enough to be seen by the eye.
D) consist mostly of empty space.

A) Atom
B) Electron
C) Molecule
D) Nucleus

A) electrons and protons are the only particles
B) no two particles can have the same energy.
C) all particles have wave properties.
D) all particles are formed by the interaction of electromagnetic waves. with mass.

A) 55.
B) 3.
C) 49.
D) 52.
E) 14.

A) they describe the position and charge of the electrons in the atoms.
B) no electrons in the world can ever have the same set of quantum numbers.
C) there are never more than 8 different sets of quantum numbers in an atom.
D) no two electrons in the same atom can have the same set of quantum numbers.

A) the angular momentum chart.
B) the periodic table of elements.
C) the chemical dictionary of Arrhenius.
D) the metric conductance/reflectance table.

A) unchanged.
B) negative.
C) positive.
D) It is impossible to remove an electron from an atom.

A) The time period of the wave describing the particle.
B) The value of the Planck's constant.
C) The energy of the particle when it has wave properties.
D) The value of the particle's position when the particle's momentum is known precisely.
E) The exact number of protons in the nucleus.

A) alpha particles interacting with nuclei to produce beta rays and alpha particles moving equally in all directions.
B) cathode rays emerging from the foil.
C) most of the alpha particles bouncing straight back with very few passing through the foil undisturbed.
D) a very few alpha particles scattered through large angles with most undergoing very little scattering.

A) correlate to the mass of each element on a row.
B) make great batteries, if you choose a metal from two separate rows.
C) exist on each diagonal, starting with hydrogen, then lithium, and so forth.
D) are displayed by elements in the same column.

A) n = 1.
B) n = 2.
C) n = 3.
D) n = 4.
E) n = 5.

A) Blackbody radiation.
B) X-rays.
C) The spectrum of atomic hydrogen.
D) Cathode rays.
E) Radioactive decay.

A) X-rays
B) Gamma rays
C) Anode rays
D) Alpha rays

A) n = 4 to n = 1.
B) n = 3 to n = 1.
C) n = 2 to n = 1.
D) n = 4 to n = 2.
E) n = 3 to n = 2.

A) electrons are repelled by the nucleus.
B) electrons lack the energy to get close to the nucleus.
C) electrons must have an angular momentum in their orbits that is not equal to zero.
D) when electrons get to the lowest possible orbit, they run out of photons to radiate.

A) Planck's constant is small and people masses are much larger than that.
B) Planck's constant is small and people move slowly.
C) Planck's constant is small and the mass of a person isn't very important.
D) Planck's constant is small and people move very fast.

A) naturally radioactive.
B) noble gases.
C) rotationally symmetric.
D) thermal equilibrium.

A) de Broglie waves.
B) helium atoms stripped of their electrons.
C) a form of electromagnetic radiation.
D) fast-moving electrons.

A) its wavelength.
B) its polarization.
C) its frequency.
D) its mass.

A) h/KE
B) h^.p
C) KE/h
D) h/p
E) p/h

A) and hydrogen are equally reactive since chemical bonding has nothing to do with the number of electrons.
B) is more reactive, since it has two electrons that can form chemical bonds.
C) is much less reactive, since its two electrons form a stable closed shell.
D) has neutrons in the nucleus.

A) Heisenberg
B) Roentgen
C) Schrödinger
D) Planck
E) Einstein

A) it has a negative charge.
B) it is a positive ion susceptible to acceleration in solar magnetic fields.
C) it is a negatively charged rubidium atom.
D) it becomes aluminum.

A) the energy of revolution of the electron in its lowest energy orbit divided by h.
B) the energy gained by the electron divided by h.
C) the energy lost by the electron divided by h.
D) the energy of revolution of the electron in its highest energy orbit divided by h.

A) boron.
B) hydrogen.
C) lithium.
D) neon.
Fill in the Blank Questions

A) gamma rays move through a magnetic field.
B) alpha rays pass through a thin metal foil.
C) beta rays are absorbed by bones.
D) cathode rays strike a metal anode.